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The leaching behaviour of a Ni-Cu-Co sulphide ore in an oxidative pressure-acid medium / Danie Strydom SmitSmit, Danie Strydom January 2001 (has links)
Hydrometallurgical processing of sulphide concentrates is an attractive method for the
selective extraction of valuable metals. The dissolution of minerals in a leaching process
involves several electrochemical parameters that need to be investigated• to ensure the
development and growth of the base metal industry in South Africa.
A study has been carried out to elucidate the leaching mechanism of a nickel-coppercobalt
sulphide concentrate in an oxidative pressure-acid medium. The sulphide
concentrate studied in this research, comprises mainly of the minerals pyrrhotite,
(Fe1_xS) with x = 0 to 0.2, pentlandite, (Ni,Fe)9S8 and chalcopyrite, (CuFeS2). The
leaching behaviour of these minerals was successfully studied by means of Atomic
Absorption (AA) measurements, Scanning '•Electron Microscopy (SEM) and Moss bauer
spectroscopy, after leaching took place in an oxidative pressure-acid medium.
The dissolution of the valuable metals was achieved effectively with recoveries of well
over 90% for nickel, copper and cobalt under the specific conditions studied.
Mechanical activation by means of ultra fine milling improved metal extraction with an
average of approximately 40%, after a leaching period of 150 minutes.
The most suitable conditions for the oxidative pressure-acid leaching of the mechanically
treated nickel-copper-cobalt sulphide concentrate in a dilute sulphuric acid medium were
found to be: particle size 80% - 10J.Lm; temperature l10°C; oxygen partial pressure 10
bar; sulphuric acid concentration 30 kg/ton; solids content 15% by mass and an impeller
agitation rate of 800 r/min. The values of the apparent activation energies of nickel,
copper and cobalt, extracted from the sulphide concentrate, were found to be 20.6 (± 4.4)
kJ/mol K, 33.6 (± 4.2) kJ/mol K and 17.4 (± 3.5) kJ/mol K respectively. / Thesis (MIng (Chemical Engineering))--Potchefstroom University for Christian Higher Education, 2001
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The leaching behaviour of a Ni-Cu-Co sulphide ore in an oxidative pressure-acid medium / Danie Strydom SmitSmit, Danie Strydom January 2001 (has links)
Hydrometallurgical processing of sulphide concentrates is an attractive method for the
selective extraction of valuable metals. The dissolution of minerals in a leaching process
involves several electrochemical parameters that need to be investigated• to ensure the
development and growth of the base metal industry in South Africa.
A study has been carried out to elucidate the leaching mechanism of a nickel-coppercobalt
sulphide concentrate in an oxidative pressure-acid medium. The sulphide
concentrate studied in this research, comprises mainly of the minerals pyrrhotite,
(Fe1_xS) with x = 0 to 0.2, pentlandite, (Ni,Fe)9S8 and chalcopyrite, (CuFeS2). The
leaching behaviour of these minerals was successfully studied by means of Atomic
Absorption (AA) measurements, Scanning '•Electron Microscopy (SEM) and Moss bauer
spectroscopy, after leaching took place in an oxidative pressure-acid medium.
The dissolution of the valuable metals was achieved effectively with recoveries of well
over 90% for nickel, copper and cobalt under the specific conditions studied.
Mechanical activation by means of ultra fine milling improved metal extraction with an
average of approximately 40%, after a leaching period of 150 minutes.
The most suitable conditions for the oxidative pressure-acid leaching of the mechanically
treated nickel-copper-cobalt sulphide concentrate in a dilute sulphuric acid medium were
found to be: particle size 80% - 10J.Lm; temperature l10°C; oxygen partial pressure 10
bar; sulphuric acid concentration 30 kg/ton; solids content 15% by mass and an impeller
agitation rate of 800 r/min. The values of the apparent activation energies of nickel,
copper and cobalt, extracted from the sulphide concentrate, were found to be 20.6 (± 4.4)
kJ/mol K, 33.6 (± 4.2) kJ/mol K and 17.4 (± 3.5) kJ/mol K respectively. / Thesis (MIng (Chemical Engineering))--Potchefstroom University for Christian Higher Education, 2001
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